Write-once optical disc, and method and apparatus for recording management information on write-once optical disc

ABSTRACT

A recording medium, and a method and apparatus for recording management information on the recording medium are discussed. According to an embodiment, the invention provides a method of recording management information on a recording medium, the recording medium including a temporary defect management area (TDMA) and a final defect management area (DMA), the DMA including a defect list area, the method comprising: recording, in the TDMA, defect list information produced while the recording medium is in use, and recording, in the defect list area of the DMA, the latest defect list information included in the TDMA when the recording medium is to be finalized, wherein the defect list area of the DMA includes a plurality of recording units, and the latest defect list information is recorded on at least one of the recording units of the defect list area.

This application is a Continuation of co-pending U.S. patent applicationSer. No. 10/670,196 filed on Sep. 26, 2003, which is incorporated byreference. This application claims the priority benefit of the KoreanApplication Nos. P2002-059341 filed on Sep. 30, 2002 and P2003-011832filed on Feb. 25, 2003, the entire contents of which are hereby fullyincorporated by reference.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a writable-once optical disc and amanagement information recording method and apparatus, and moreparticularly, to a method and apparatus for efficiently recordingmanagement information on a writable-once optical disc.

2. Discussion of the Background Art

Optical disc, which is a kind of optical recording media and can recorda large amount of data, is widely being used. Today, a kind ofinnovative high-density digital versatile disc (HD-DVD) such as a blueray disc (Blu-ray Disc), which can record and store video data of highquality and audio data of high fidelity for a long time, is underdevelopment.

The Blu-ray disc is a next generation optical recording solution thatcan store a larger amount of data than a conventional DVD. The Blu-raydisc employs a blue-violet laser with the wavelength of 405 nm which isshorter than the wavelength of 650 nm of a red laser used to access aconventional DVD. The Blu-ray disc has generally a thickness of 1.2 mmand a diameter of 12 cm. It includes a light transmission layer whosethickness is 0.1 mm so that the Blu-ray disc can store a larger amountof data than the current DVDs.

Various standards related to the Blu-ray discs are in development. Amongthe different types of Blu-ray discs, a Blu-ray Disc Rewritable (BD-RE)and a Blu-ray Disc Write-Once (BD-WO) are being developed.

FIG. 1 schematically illustrates a structure of a recording area of ageneral BD-RE. Referring to FIG. 1, the BD-RE includes a recording layerdivided into a lead-in area, a data area and a lead-out area. The dataarea includes a user data area for recording user data thereon, and aninner spare area ISA0 and an outer spare area OSA0 each allocated in theinner tracks and the outer tracks of the disc. These spare areas areused as replacement areas for replacing data in a defective area of theuser data area according to linear replacement.

In the BD-RE, if a defective area is found in the user data area duringrecording, data in the defective area is transferred to and recorded ona spare area. Further, as defect management information for managing thedefective area, position information and the like relating to thedefective area and the corresponding spare area are recorded on defectmanagement areas (DMA 1˜DMA 4) in the lead-in area and the lead-outarea. Also, since data can be recorded on and erased from any area ofthe BD-RE repeatedly (since the BD-RE is rewritable), the entire BD-REcan be randomly used irrespective of a specific recording mode.

In contrast, in a writable-once Blu-ray disc (BD-WO), data can berecorded only one time on a specific area of the disc. As a result, theBD-WO has certain limitations pertaining to recording modes and inrandomly using the entire area of the disc due to the defect managementdifficulty.

Further, in a BD-WO, management of the defective areas is one of theimportant matters that needs to be addressed, especially for datarecording operations. But since the BD-WO is still in the earlydevelopment stage, there are no schemes, no disc structures, noapparatuses, and no methods on how to manage the defective areas of theBD-WO and record management information on the BD-WO, which will beneeded for the BD-WO to be commercially viable and operationallyfeasible. Accordingly, for the BD-WO, a unified specification isrequired that would satisfy the aforementioned advanced requirements.But any proposed specification relating to the current BD-RE cannot beused because it does not address the needs of the BD-WO.

SUMMARY OF THE INVENTION

Accordingly, the present invention is directed to a recording medium anda management information recording method and apparatus thatsubstantially obviate one or more problems due to limitations anddisadvantages of the background art.

An object of the present invention is to provide a method of recordingdisc management information such as timing, contents and locationinformation in a plurality of management areas of a write-once opticaldisc.

Additional advantages, objects, and features of the invention will beset forth in part in the description which follows and in part willbecome apparent to those having ordinary skill in the art uponexamination of the following or may be learned from practice of theinvention. The objectives and other advantages of the invention may berealized and attained by the structure particularly pointed out in thewritten description and claims hereof as well as the appended drawings.

To achieve these objects and other advantages and in accordance with thepurpose of the invention, as embodied and broadly described herein, amethod of recording management information on a write-once opticalrecording medium, the recording medium including a temporary defectmanagement area (TDMA) and a final defect management area (DMA),includes: recording, in the TDMA, management information produced whilethe recording medium is in use; and transferring and recording thelatest management information of the TDMA in the DMA at a DMA fill-instage of the recording medium.

In accordance with an aspect of the invention, a method of recordingmanagement information on a write-once optical recording medium, therecording medium including a temporary defect management area (TDMA) anda final defect management area (DMA), the DMA including a defect listarea for storing therein defect list information, includes: if no defectmanagement is to be performed on the recoding medium, setting apredetermined value in the defect list area of the DMA; recording, inthe TDMA, management information produced while the recording medium isin use; and transferring and recording the latest management informationof the TDMA in the DMA when the recording medium is to be finalized.

In accordance with another aspect of the invention, an apparatus forrecording management information on a write-once optical recordingmedium, the recording medium including a temporary defect managementarea (TDMA) and a final defect management area (DMA), includes acombination of elements configured for: recording, in the TDMA,management information produced while the recording medium is in use;and transferring and recording the latest management information of theTDMA in the DMA at a DMA fill-in stage of the recording medium.

In accordance with another aspect of the invention, an apparatus forrecording management information on a write-once optical recordingmedium, the recording medium including a temporary defect managementarea (TDMA) and a final defect management area (DMA), the DMA includinga defect list area for storing therein defect list information, includesa combination of elements configured for: setting a predetermined valuein the defect list area of the DMA if no defect management is to beperformed on the recoding medium; recording, in the TDMA, managementinformation produced while the recording medium is in use; andtransferring and recording the latest management information of the TDMAin the DMA when the recording medium is to be finalized.

In accordance with another aspect of the invention, a write-once opticalrecording medium for recording management information thereon, includes:at least one recording layer including a temporary defect managementarea (TDMA) and a final defect management area (DMA), wherein managementinformation produced while the recording medium is in use is recorded inthe TDMA, and the latest management information of the TDMA istransferred and recorded in the DMA at a DMA fill-in stage of therecording medium.

In accordance with another aspect of the invention, a write-once opticalrecording medium for recording management information thereon, includes:at least one recording layer including a temporary defect managementarea (TDMA) and a final defect management area (DMA), the DMA includinga defect list area for storing therein defect list information, whereinif no defect management is to be performed on the recoding medium, apredetermined value is set in the defect list area of the DMA;management information produced while the recording medium is in use isrecorded in the TDMA; and the latest management information of the TDMAis transferred and recorded in the DMA when the recording medium is tobe finalized.

In accordance with another aspect, the present invention provides amethod of recording management information on a recording medium, therecording medium including a temporary defect management area (TDMA) anda final defect management area (DMA), the DMA including a defect listarea, the method comprising: recording, in the TDMA, defect listinformation produced while the recording medium is in use; andrecording, in the defect list area of the DMA, the latest defect listinformation included in the TDMA when the recording medium is to befinalized, wherein the defect list area of the DMA includes a pluralityof recording units, and the latest defect list information is recordedon at least one of the recording units of the defect list area.

In accordance with another aspect, the present invention provides anapparatus for recording management information on a recording medium,the recording medium including a temporary defect management area (TDMA)and a final defect management area (DMA), the DMA including a defectlist area, the apparatus comprising: a unit for recording, in the TDMA,defect list information produced while the recording medium is in use;and a unit for recording, in the defect list area of the DMA, the latestdefect list information included in the TDMA when the recording mediumis to be finalized, wherein the defect list area of the DMA includes aplurality of recording units, and the latest defect list information isrecorded on at least one of the recording units of the defect list area.

In accordance with another aspect, the present invention provides arecording medium for storing information, the recording mediumcomprising: a temporary defect management area (TDMA) for storing defectlist information, while the recording medium is in use; and a finaldefect management area (DMA) for storing the latest defect listinformation included in the TDMA when the recording medium is to befinalized, wherein the DMA includes a defect list area having aplurality of recording units, and the latest defect list information isrecorded on at least one of the recording units of the defect list area.

It is to be understood that both the foregoing general description andthe following detailed description of the present invention areexemplary and explanatory and are intended to provide furtherexplanation of the invention as claimed.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings, which are included to provide a furtherunderstanding of the invention and are incorporated in and constitute apart of this application, illustrate embodiment(s) of the invention andtogether with the description serve to explain the principle of theinvention. In the drawings:

FIG. 1 schematically illustrates a structure of a general single-layerBD-RE:

FIG. 2 is a block diagram of an optical recording/reproducing deviceaccording the present invention;

FIG. 3 illustrates a structure of a writable-once optical disc such as asingle layer BD-WO according to an embodiment of the present invention;

FIG. 4 illustrates an example of a DDS structure on a rewritable disc, aTDDS structure on a BD-WO and a disc management information recordingmethod for the BD-WO according to an embodiment of the presentinvention;

FIG. 5 illustrates a structure of a writable-once optical disc such as asingle layer BD-WO according to another embodiment of the presentinvention;

FIG. 6A shows an exemplary structure of a DMA of a single-layer BD-WOaccording to an embodiment of the present invention;

FIG. 6B illustrates the structure of the DMA of FIG. 6A, a TDMAstructure and a method of transferring data from the TDMA to the DMAaccording to an embodiment of the present invention;

FIG. 6C shows an exemplary structure of a DMA of a dual-layer BD-WOaccording to an embodiment of the present invention;

FIG. 7 shows a chart for explaining the timing, contents and locationinformation associated with the DMA fill-in process of a BD-WO accordingto a first embodiment of the present invention;

FIG. 8 shows a chart for explaining the timing, contents and locationinformation associated with the DMA fill-in process of a BD-WO accordingto a second embodiment of the present invention;

FIG. 9A shows a chart for explaining the timing, contents and locationinformation associated with the DMA fill-in process of a BD-WO accordingto a third embodiment of the present invention;

FIG. 9B shows an example of the DMA to which the DMA fill-in process ofFIG. 9A is applied; and

FIG. 10 shows examples of values of a TDDS/DDS status flag recorded aspart of the DDS information in the DDS section of the DMA according tothe present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Reference will now be made in detail to the preferred embodiments of thepresent invention, examples of which are illustrated in the accompanyingdrawings. Wherever possible, the same reference numerals will be usedthroughout the drawings to refer to the same or like parts.

FIG. 2 is an example of a block diagram of an optical discrecording/reproducing device 20 according to an embodiment of thepresent invention. The optical disc recording/reproducing device 20includes an optical pickup 22 for writing/reading data to/from anoptical recording medium 21, a servo unit 23 for controlling the pickup22 to maintain a distance between an objective lens of the pickup 22 andthe recording medium 21 and for tracking relevant tracks on therecording medium 21, a data processor 24 for processing and supplyinginput data to the pickup 22 for writing, and for processing data readfrom the recording medium 21, an interface 25 for exchanging data and/orcommands with any external host 30, a memory or storage 27 for storinginformation and data therein including defect management data as needed(e.g., temporary defect management information, etc.) associated withthe recording medium 21, and a microprocessor or controller 26 forcontrolling the operations and elements of the recording/reproducingdevice 20. Data to be written/read to/from the recording medium 21 mayalso be stored in the memory 27 if needed. All the components of therecording/reproducing device 20 are operatively coupled. The recordingmedium 21 is a recording medium of write-once type such as a BD-WO.

All the methods and disc structures discussed herein according to thepresent invention can be implemented using the recording/reproducingdevice 20 of FIG. 2 or any other suitable device/system. For example,the microcomputer 26 of the device 20 may be used to control allocationof the disc structure and to control the recording of managementinformation on the recording medium and the transferring of themanagement information from a temporary area (e.g., TDMA) to a permanentor final area (e.g., DMA) on the recording medium 21. The TDMA and DMAwill be discussed later in more detail.

A management information recording method for a writable-once opticaldisc such as a BD-WO according to the preferred embodiments of thepresent invention will be now described in detail with reference to theaccompanying drawings. For a discussion convenience, a writable-onceBlu-ray disc (BD-WO) will be exemplified. Herein, two types of a BD-WO—asingle layer BD-WO and a dual layer BD-WO—are discussed. The singlelayer BD-WO has a single recording layer, whereas the dual layer BD-WOhas two recording layers.

FIG. 3 illustrates a structure of a writable-once optical recordingmedium such as a single-layer BD-WO according to an embodiment of thepresent invention. Referring to FIG. 3, the BD-WO includes a lead-inarea, a data area, and a lead-out area allocated on the single recordinglayer. Each of the lead-in area and the lead-out area includes aplurality of defect management areas (DMA 1 and DMA 2; DMA 3 and DMA 4)for storing therein DMA information for defect management. Each of theDMAs 1-4 has a fixed size, e.g., 32 clusters. Generally, in view of theimportance of defect management, the same information is written in eachof the DMAs 1-4 so that if one of the DMAs is defective, then adifferent DMA can be accessed to obtain the defect managementinformation.

It should be noted that in a general BD-RE, since data can be repeatedlyrecorded on and erased from a DMA (although the size of the DMA islimited), a DMA of large size is not required. However, in a BD-WOaccording to the present invention, since data cannot be repeatedlyrecorded on and erased from the DMA, a DMA of large size is required fordefect management.

Still referring to FIG. 3, the lead-in area further includes a temporarydefect management area (TDMA 1) for temporarily storing defectmanagement information therein. The data area includes an inner sparearea ISA0, a user data area, and an outer spare area OSA0. Parts of orthe entire ISA0 and OSA0 are used as replacement areas for defectiveareas in the user data area according to linear replacement. Forinstance, during a recording of data into the user data area, if adefective area in the user data area is detected, then the data writtenor to be written to this defective area is transferred to a spare area(e.g., ISA0 or OSA0) according to a linear replacement scheme. The outerspare area OSA0 includes a temporary defect management area (TDMA 2).The defect management information temporarily stored in the TDMA 1and/or TDMA 2 is also referred to herein as TDMA information.

In one embodiment, the TDMA 1 allocated to the lead-in area has a fixedsize, whereas the TDMA 2 allocated to the outer spare area OSA0 has avariable size depending upon the size of the spare area(s). For example,if the OSA0 has a size of N×256 clusters where N>0 (N=integer), then theTDMA 2 has a size of P clusters where P=(N×256)/4.

In one example, the same information may be written in each of the TDMAs1 and 2. In another example, the TDMAs 1 and 2 may be sequentially usedto sequentially record the TDMA information. Regardless, duringreplacement writing operations for writing data of a defective area ontoa spare area, TDMA information is generated (e.g., under control of themicrocomputer 26) and written onto the TDMAs 1 and/or 2. The TDMAs arealso updated periodically or as needed. When the BD-WO is ready to befinalized or the DMA is to be filled in for other reasons, then the TDMAinformation (latest version) temporarily written in the TDMA(s) istransferred and written onto one or each of the DMAs 1-4. This transferprocess will be discussed later in more detail.

The TDMA information written in each of the TDMAs 1 and 2 includestemporary defect list (TDFL) information and temporary disc definitionstructure (TDDS) information. In one embodiment, the TDFL informationincludes one or a plurality of TDFLs (TDFL #1˜TDFL #n). Each TDFLincludes one or a plurality of defect entries identifying defects andcorresponding replacement areas on the disc. Each defect entry includeslocation information pertaining to a defective area of the user dataarea and the corresponding replacement area. For example, during a datarecording operation on the BD-WO, if a defective area is found in theuser data area, then data written or to be written in that defectivearea is written in a part (replacement area) of a spare area (e.g., ISA0or OSA0) according to a linear replacement scheme. Then the informationpertaining to the defective area and the replacement area and theirrelationship is entered as a defect entry in the TDFL. For instance,this information may include a first physical sector number of thedefective area on the disc, a first physical sector number of thereplacement area (spare area) corresponding to that defective area, andany other data pertaining to the defect for defect management.

In one embodiment, the TDDS information written in each of the TDMAs 1and 2 includes one or a plurality of TDDSs (TDDS #1˜TDDS #n). Each TDDShas a fixed size (e.g., one cluster) and includes location informationpertaining to the TDFL(s) so that the location of any TDFL can bequickly identified by accessing the TDDS(s). This location informationcan be written in a portion of Sector 0 of the one cluster, and mayinclude one or more physical sector numbers each indicating a locationof a TDFL written on the BD-WO, and any other information pertaining tothe TDFL information. Here, a cluster has 32 sectors each sector having2048 bytes.

Each TDDS also includes recording mode information (RM). The recordingmode information identifies a recording mode of the BD-WO and can bewritten in a portion of Sector 0 of the one cluster. The locationinformation pertaining to the TDFL(s) and the recording mode informationdiscussed above are referred to herein as a TDDS part. Here, the TDDSpart occupies the entire Sector 0 of the cluster (or any otherdesignated location area).

Each TDDS also includes disc usage management information whichidentifies the status of a recording area of the BD-WO and which can berepresented in one of the two forms: track information (Track-Info) andspace bitmap information (SBM). This structure of the TDDS will bediscussed in more detail later by referring to FIG. 4.

As the data recording operation for writing data into the data areaprogresses, the TDMAs may be updated periodically to reflect anyrecently discovered defective areas and corresponding replacement areas.After each updating of the TDMA, a TDFL and a corresponding TDDS, whichmay include all previous TDMA information and the recently generatedTDMA information, may be written in the TDMA. In this aspect, the latestTDDS and TDFL written in the TDMA of the BD-WO would include the latestTDMA information. Then when the BD-WO is to be finalized or the DMA(s)is ready to be filled in, the latest TDDS and TDFL written on the BD-WOare transferred and written in one or each of the DMAs 1-4 as the finaland most-updated defect management information.

FIG. 4 illustrates a DDS structure of a rewritable disc, an example of aTDDS structure on a BD-WO and a disc management information recordingmethod for the BD-WO according to an embodiment of the presentinvention. As shown in FIG. 4, in the DDS of a general rewritableoptical disc, only 60 byte information corresponding to an extremelysmall portion of 1 cluster is used to store therein the DDS information.The entire remaining part of the DDS is all set to ‘zero padding’.

In contrast, in the BD-WO, the entire TDDS area is used to store thereinthe TDDS information. As shown in FIGS. 3 and 4, the TDDS part(including the location information and the recording mode information)is written in the entire Sector 0 of the cluster assigned as the TDDS,whereas Sectors 1-31 store therein the disc usage management information(Track-Info or SBM). In another example, the disc usage managementinformation can be recorded on the first 31 sectors (Sectors 0˜30) inthe TDDS, and any remaining disc usage management information can berecorded on the last 32^(nd) sector (Sector 31) in the TDDS along withthe TDDS part.

The recording mode information identifies one of a plurality ofrecording modes employed in the BD-WO according to the presentinvention. In this example, a value of “0000 0000” may be used toindicate a sequential recoding mode, and a value of “0000 0001” may beused to indicate a random recording mode. Obviously, other examples arepossible. Information about the BD-WO according to the present inventioncan be variously determined depending upon the needs through a processof specification regulation.

The disc usage management information is varied in dependence upon thedisc usage. In the BD-WO, the disc usage management information isrequired for accurately searching and detecting the start point of anavailable recording area, and is used to distinguish a recording areafrom a non-recording area on the disc. In this aspect, the disc usagemanagement information indicates where the available recording area andthe recorded area are located within the data area (e.g., user dataarea).

As mentioned above, the disc usage management information can berepresented as either the track information (Track-Info) or the spacebitmap information (SBM). The Track-Info is generally used when theBD-WO is recorded in a sequential recording mode. The SBM is generallyused when the BD-WO is recorded in a random recording mode. Theserecording modes can be determined depending on the recording modeidentified in the recording mode information stored in the TDDS.

In conventional writable-once optical discs, the recording status/modeinformation is expressed as ‘track information’ in case of compact discseries, and as ‘Rzone’, ‘Fragment’ or ‘recording range’ in case of DVDseries. But in the present invention, the aforementioned variousexpressions relating to the recording status/mode information arecommonly designated as ‘Track-Info’, and accordingly the Track-Info willbe appreciated as having such meaning irrespective of expressions.

In one example, since the tracks on the BD-WO are sequentially used torecord during the sequential recording mode, the Track-Info identifiesthe start point (location) of the recording area (e.g., user data area)of the BD-WO, and the end point (location) of the last recorded portionof the recording area. This information then indicates the start of thenext available portion of the recording area on the BD-WO.

The bitmap information identifies a start point of an availablerecordable portion of the recording area on the BD-WO using bit valuessuch as ‘0’ and ‘1’. For instance, if a particular cluster area of therecording area on the BD-WO has been recorded, then it is indicated byallocating a value of ‘1’ to every minimal recording unit (1 cluster).If a cluster area of the recording area has no recorded data thereon,then that cluster is assigned to a value of ‘0’. In this manner, if theSBM indicates that a particular cluster has a value of ‘1’ assignedthereto, then it indicates that that cluster has been already used(i.e., it has recorded data thereon). If the SBM indicates that aparticular cluster has a value of ‘0’, then it indicates that thatcluster has not been used yet (i.e., it has no recorded data thereon).Obviously, the reversal or some other values may be used to indicate therecording/non-recording state of each area unit such as the clusters ofthe user data area. Thus, the SBM makes it possible to express arecording usage status of the disc even in the random recording mode.

FIG. 5 illustrates a structure of a writable-once optical disc such as asingle layer BD-WO according to another embodiment of the presentinvention. The BD-WO structure of FIG. 5 is identical to the BD-WOstructure of FIG. 3, except that the TDDS part, which includes thelocation information of the TDFL(s) and the recording mode information,is updated and written after each update state as shown in FIG. 5. Inthis aspect, the disc usage management information (Track-Info or SBM)is stored in Sectors 0-30 of one cluster of the TDMA, and the TDDS partand RM are stored in Sector 31 of the one cluster. The TDDS partoccupies the entire Sector 31 of the cluster. In another example, theTDDS part may be stored in the entire Sector 0 of one cluster of theTDMA, and the Track-Info or SBM may be stored in Sectors 1-31 of the onecluster.

Now, the method of transferring the TDMA information from the TDMA tothe DMA according to the embodiments of the present invention will beexplained by referring to FIGS. 6A-10. This transfer process is alsocalled a DMA fill-in process.

FIG. 6A shows an exemplary structure of a DMA of a single-layer BD-WO,and FIG. 6B illustrates the structure of the DMA of FIG. 6A, a TDMAstructure and a method of transferring data from the TDMA to the DMAaccording to an embodiment of the present invention. The DMA shown inFIGS. 6A and 6B equals one or each of the DMAs 1-4 shown in FIG. 3.

Referring to FIGS. 6A and 6B, the DMA is composed of 32 clusters. TheClusters 1-4 of the DMA are designated as a DDS section, whereas theClusters 5-32 of the DMA are designated as a DFL section. All theclusters of the DMA in the BD-WO are designated for storing managementdata.

During the DMA fill-in process, the latest TDDS information from theTDMA is transferred to and recorded in each of Cluster 1 to Cluster 4 ofthe DMA as DDS information. That is, the latest TDDS part (TO)(including the TDFL location information and the recording modeinformation) and the latest disc usage management information(Track-Info or SBM) (DO) of the TDDS information are transferred ontothe DMA. As a result, the same DDS information is four times recorded inthe DMA. The latest TDFL information from the TDMA is also transferredto and recorded in Clusters 5-32 of the DMA as DFL information. Here,the same DFL information can be recorded in the DMA up to seven times bydesignating four clusters of the DMA for recording the DFL informationtherein. In one example, the TDDS part written in the DDS section of theDMA may identify the location of the DFLs in the DMA on the BD-WO, andnot necessarily the location of the TDFLs in the TDMA on the BD-WO.Storing the same information repeatedly in the DDS section or the DFLsection ensures that the DMA information is not lost (e.g., due to adefect in a portion of the DMA) and is accurately and completelyaccessed each time it is needed.

FIG. 6C shows an exemplary structure of a DMA of a dual-layer BD-WOaccording to an embodiment of the present invention. Referring to FIG.6C, one DMA of the dual-layer BD-WO is composed of a DMA part (Clusters1-32) from a first recording layer L0 of the BD-WO, and a DMA part(Clusters 33-64) from a second recording layer (L1) of the BD-WO, whichare accessed according to the tracking direction indicated with thearrow. The same DDS information (e.g., for both recording layers) isrepeatedly recorded on the Clusters 1-8 of the DMA, and the same DFLinformation is repeatedly recorded on the Clusters 9-64 of the DMA, upto the maximum of, e.g., seven times. In addition, the BD-WO includes alead-in area, a data area and an outer zone area on the first recordinglayer, and a lead-out area, a data area and an outer zone area on thesecond recording layer. Each of the data areas may include at least onespare area and a user data area. The lead-in area of the first recordinglayer may include a TDMA and first and second DMAs. The lead-out area ofthe second recording layer may include another TDMA and first and secondDMAs. Here, as an example, one DMA shown in FIG. 6C may be composed ofthe first DMAs from the first and second recording layers, or of thesecond DMAs from the first and second recording layers. Additional DMAsmay also be provided in the outer zone areas. The spare area(s) mayinclude additional TDMA(s).

Similar to the single layer BD-WO, the TDMAs in the lead-in/lead-outarea of the dual layer BD-WO may have a fixed size, whereas the TDMAs inthe spare areas may have a variable size depending upon the size of thespare area(s). The use and structure of the DMAs and TDMAs on the singlelayer BD-WO as discussed herein applies equally to the DMAs and TDMAs onthe dual layer BD-WO.

In one embodiment, the latest disc usage management information isrecorded each on the front part of a first DMA in the lead-in areaand/or on the front/rear part of a DMA in the lead-out area (dependingon whether the disc has a single or multiple recording layers). Thisallows the disc usage management information to be accessed quickly atthe initial loading time of the disc. Further, the data reliability anddata preservation can be assured by repetitive recording of sameinformation in different parts of the disc.

FIG. 7 shows a chart for explaining the timing, contents and locationinformation associated with the DMA fill-in process of a BD-WO accordingto a first embodiment of the present invention. This DMA fill-in processis applicable to the BD-WO structures shown in FIGS. 3 and 5-6C, orother suitable BD-WO structures.

Referring to FIG. 7, the time for transferring the TDMA information intothe DMA of the BD-WO is when the BD-WO is to be finalized. Defectmanagement is performed on the BD-WO. As a result, the TDMA informationproduced while the BD-WO is in use is recorded in the TDMA, and when theBD-WO is to be finalized, the latest TDMA information from the TDMA istransferred to and recorded in the DMA.

The time for finalization is generally divided into three cases. Thefirst case (50 a) is when no more recording is performed on the BD-WO(e.g., data recording in the user data area is completed, or no userdata area remains on the disc). The second case (50 b) is when the TDMAis full of data and no further TDMA information can be recorded therein.As one example only, this case may occur if the entire TDMA(s) forrecording the TDMA information have been used. The third case (50 c) iswhen the user requests a finalization of the BD-WO. As one example only,the user or host may request the finalization of the BD-WO even thoughsome user data area or the TDMA is not full, or even though the userdata recording in the user data area is not completed.

In all three cases of timing, the contents transferred from the TDMA tothe DMA are the latest TDDS information (the latest TDDS part and thelatest disc usage management information) and the latest TDFLinformation written in the TDMA of the BD-WO. The latest TDDSinformation and the latest TDFL information written in the TDMA aretransferred to a DDS section and a DFL section of the DMA, respectively,during the DMA fill-in process.

FIG. 8 shows a chart for explaining the timing, contents and locationinformation associated with the DMA fill-in process of a BD-WO accordingto a second embodiment of the present invention. This DMA fill-inprocess is applicable to the BD-WO structures shown in FIGS. 3 and 5-6Cor other suitable BD-WO structures.

The second embodiment addresses a scenario when the defect management(DM) on the BD-WO is not to be performed. Whether or not the DM is to beperformed on the BD-WO can be determined during the initialization ofthe BD-WO or some other time based on known factors such as a user orhost command not to perform defect management, etc. Referring to FIG. 8,if it is determined that the DM is not be performed (50 d) on the BD-WO(e.g., when the disc is initialized), then a specified value, sign orother indication is set in a DFL section of the DMA. This indicationindicates that no DM is performed on the BD-WO (e.g., no defect listsare recorded on the BD-WO or no linear replacement schemes are performedto transfer the data of a defective user area to a replacement/sparearea). When no DM is to be performed, A/V (audio/video) data can berecorded in real time. Here, since no DM is performed during the discrecording (e.g., into the user data area), no TDFLs are generated andthe predetermined value or some other fixed indication can be set in theDFL section of the DMA. In one example, the predetermined value forindicating no DM is set in the DFL section of the DMA in advance beforethe finalization of the BD-WO (e.g., at the disc initialization). Atthis time, the entire DFL section of the DMA may be padded with the zerovalue. In another variation, a predetermined value (e.g., zero) or someother indication may be set in the TDFL area of the TDMA, and then thisvalue (TDFL information) may be transferred to the DFL section of theDMA while the TDDS information is transferred to the DDS section of theDMA during the DMA-fill in process (i.e., at the finalization of theBD-WO).

The process of transferring the TDDS information from the TDDS of theTDMA to the DDS section of the DMA in the second embodiment is identicalto that of the first embodiment of FIG. 7. More specifically, after itis determined that no DM is to be performed on the BD-WO and then whenthe BD-WO is ready to be finalized, then the latest TDDS information istransferred to the DDS section of the DMA. As shown in FIG. 8, duringthe finalization of the BD-WO, in the first case (50 a) when no morerecording is performed on the BD-WO, in the second case (50 b) when theTDMA is full, and in the third case when the user requests finalizationof the BD-WO, the latest TDDS information from the TDMA is transferredand recorded in the DDS section of the DMA as part of DMA fill-inprocess.

For example, if the DMA fill-in process of FIG. 8 is applied to the DMAstructure of FIG. 6A, the Clusters 1-4 of the DMA would store thereinthe predetermined value (e.g., zero), and the latest TDDS information(e.g., the latest TDDS part and the latest disc usage managementinformation) from the TDMA is transferred and recorded in the DDSsection of the DMA. AS discussed above, the same latest TDDS informationcan be recorded up to seven times in the Cluster 5-32 of the DMA. Thatis, in the maximum 7 repetition recording, the same latest TDDSinformation is written in the Clusters 5-8, the Cluster 9-12, theCluster 13-16, . . . and the Clusters 29-32 of the DMA.

FIG. 9A shows a chart for explaining the timing, contents and locationinformation associated with the DMA fill-in process of a BD-WO accordingto a third embodiment of the present invention. This DMA fill-in processis applicable to the BD-WO structures shown in FIGS. 3 and 5-6C or othersuitable BD-WO structures.

The third embodiment addresses a scenario when no more data can berecorded in the user data area of the BD-WO, but the spare area(s) andthe TDMA(s) are not full and can still be used to perform defectmanagement. If any recordable area remains in the spare area (e.g., ISA0and OSA0) and the TDMA (e.g., TDMAs 1 and 2) even though no morerecordable area exists in the user data area of the BD-WO (e.g., becausethe user data area is full, etc.), then at that time, the latest TDDSinformation (e.g., the latest TDDS part and the latest disc usagemanagement information) and the latest TDFL information from the TDMAare transferred and recorded into an area of the DMA. Subsequently, whenthe BD-WO is ready to be finalized, the latest TDDS information and thelatest TDFL information at that time from the TDMA are transferred andrecorded into another area of the DMA, such as the remaining area of theDMA.

Referring to FIG. 9A, in this embodiment, the DM is performed evenduring the reproduction of the BD-WO. Particularly, if the spare areaand the TDMA are not full and are available for use in the DM eventhough the recordable user data area is not available (50 e), the latestTDMA information of the TDMA at this time is transferred and recorded inonly a partial area of the DMA before the finalization of the BD-WO.Subsequently, when the BD-WO is to be finalized (50 b or 50 c), thelatest TDMA information of the TDMA at that time is then transferred andrecorded in the remaining or another area designated of the DMA.

Here, the time for finalization is divided into two cases 50 b and 50 c,which are identical to the two cases 50 b and 50 c in FIG. 7. Briefly,the first case (50 b) is when the TDMA is full of data and no furtherTDMA information can be recorded therein. The second case (50 c) is whenthe user requests a finalization of the BD-WO.

FIG. 9B shows an example of the DMA to which the DMA fill-in process ofFIG. 9A is applied. As shown in FIG. 9B, when the situation 50 e occurs,the latest TDDS information is written as DDS information into twoclusters (e.g., Clusters 1 and 2) of the DMA, and the latest TDFLinformation is written as DFL information into four clusters (e.g.,Clusters 5-8) of the DMA. Here the latest TDFL information is writtenonce in Clusters 5-8 without any repetition. Then when the disc is to befinalized (50 b or 50 c), the latest TDDS information of that time iswritten as DDS information into two clusters (e.g., Clusters 3 and 4) ofthe DMA and the latest TDFL information of that time is written as DFLinformation into the remaining clusters of the DMA. For instance, thesame TDFL information can be written up to six times in the Clusters9-32 of the DMA. Other variations are possible.

FIG. 10 shows examples of values of a TDDS/DDS status flag recorded aspart of the DDS information in the DDS section of the DMA according tothe present invention. Such status flag can be used in all the discstructures and methods discussed herein according to the differentembodiments of the present invention. This status flag informs the user,host or other entity under which status/case the TDDS or DDS informationhas been recorded on the BD-WO. The TDDS or DDS status flag may be ofone-byte size or some other size.

For instance, in each of the above-discussed first to third embodimentsof the present invention, the DDS information written in the DDS sectionof the DMA may include a DDS status flag. Similarly, the TDDSinformation written in the TDMA may include a TDDS status flag. Onestatus flag having different values may be used to indicate differentrecording statuses of the TDDS and DDS information. In the alternative,separate TDDS status flag and DDS status flag can be used.

Referring to FIG. 10, if the same status flag is used for both the TDDSand DDS information, then the status flag of ‘0000 0000’ may mean thatthe BD-WO is finalized in response to the user's request (50 c) and thatthe management information (e.g., DDS information) is recorded in theDMA. The status flag of ‘0000 1111’ may mean that the BD-WO is finalizedbecause no more recording is allowed in the user data area (50 a) andthat the management information (e.g., DDS information) is recorded inthe DMA. The status flag of ‘1111 0000’ may mean that the BD-WO isfinalized because the TDMA is full (50 b) and that the managementinformation (e.g., DDS information) is recorded in the DMA. The statusflag of ‘1111 1111’ may mean that the management information (e.g., TDDSinformation) is recorded in the TDMA while the disc is in use. Obviouslyother variations or status flag values are possible.

Using the status flag discussed above, the status of the BD-WO can bedetermined or confirmed. For instance, when the disc is loaded forreproduction, the TDDS/DDS status flag value can be examined todetermine under what circumstances and in what manner the DMA fill-inprocess occurred on the disc. Thus, the efficient use of the disc can beassured.

It will be apparent to those skilled in the art than variousmodifications and variations can be made in the present invention. Thus,it is intended that the present invention covers the modifications andvariations of this invention provided they come within the scope of theappended claims and their equivalents.

1. A method of recording management information on a recording medium,the recording medium including a temporary defect management area (TDMA)and a final defect management area (DMA), the DMA including a defectlist area, the method comprising: recording, in the TDMA, defect listinformation produced while the recording medium is in use; andrecording, in the defect list area of the DMA, the latest defect listinformation included in the TDMA when the recording medium is to befinalized, wherein the defect list area of the DMA includes a pluralityof recording units, and the latest defect list information is recordedon at least one of the recording units of the defect list area.
 2. Themethod of claim 1, wherein the DMA further includes a disc definitionstructure area, and the method further comprises: recording, in theTDMA, disc definition structure information produced while the recordingmedium is in use; and recording, in the disc definition structure areaof the DMA, the latest disc definition structure information included inthe TDMA when the recording medium is to be finalized, wherein the discdefinition structure area of the DMA includes a plurality of recordingunits, and the latest disc definition structure information is recordedon at least one of the recording units of the disc definition structurearea.
 3. An apparatus for recording management information on arecording medium, the recording medium including a temporary defectmanagement area (TDMA) and a final defect management area (DMA), the DMAincluding a defect list area, the apparatus comprising: means forrecording, in the TDMA, defect list information produced while therecording medium is in use; and means for recording, in the defect listarea of the DMA, the latest defect list information included in the TDMAwhen the recording medium is to be finalized, wherein the defect listarea of the DMA includes a plurality of recording units, and the latestdefect list information is recorded on at least one of the recordingunits of the defect list area.
 4. The apparatus of claim 3, wherein theDMA further includes a disc definition structure area, and the apparatusfurther comprises: means for recording, in the TDMA, disc definitionstructure information produced while the recording medium is in use; andmeans for recording, in the disc definition structure area of the DMA,the latest disc definition structure information included in the TDMAwhen the recording medium is to be finalized, wherein the discdefinition structure area of the DMA includes a plurality of recordingunits, and the latest disc definition structure information is recordedon at least one of the recording units of the disc definition structurearea.
 5. A recording medium for storing information, the recordingmedium comprising: a temporary defect management area (TDMA) for storingdefect list information, while the recording medium is in use; and afinal defect management area (DMA) for storing the latest defect listinformation included in the TDMA when the recording medium is to befinalized, wherein the DMA includes a defect list area having aplurality of recording units, and the latest defect list information isrecorded on at least one of the recording units of the defect list area.6. The recording medium of claim 5, wherein the DMA further includes adisc definition structure area having a plurality of recording units,the TDMA is used for storing disc definition structure information,while the recording medium is in use, and the DMA is used for storingthe latest disc definition structure information included in the TDMAwhen the recording medium is to be finalized, wherein the latest discdefinition structure information is recorded on at least one of therecording units of the disc definition structure area.